Kryon has said to look for evidence that the
magnetic fields all around us,
produced by the electrical power sources
in our homes, businesses, and
communities, have direct effects on our health
and well-being. This
article from Science News shows how researchers
have found that magnetic
fields directly affect the actions of drug
therapy from traditional
medicine....
Kathy
Magnetic fields can diminish drug action
by J. Raloff
The low-level electromagnetic fields present
in some North American homes
today can diminish or wipe out a widely prescribed
drug's action, at least
in test tubes. Researchers have found that
when exposed to such fields, the
drug tamoxifen lost its ability to halt the
proliferation of cancer cells
grown in the laboratory. Tamoxifen is a synthetic
hormone used to prevent
the recurrence of breast cancer.
These findings, reported last week at a Washington,
D.C., meeting sponsored
by the U.S. Public Health Service, also heighten
concern that these
electromagnetic fields may be triggering
hitherto unrecognized biological
changes in people.
The new study is an extension of research
that Robert P. Liburdy, a cell
biologist at Lawrence Berkeley (Calif.) National
Laboratory, reported on 4
years ago. At that time, he showed that while
melatonin, a natural
antioxidant hormone, would inhibit the growth
of breast cancer cells
exposed to 2 milligauss (mG) magnetic fields,
its activity was essentially
erased when the cells were bathed in a 12
mG field (SN: 7/3/93, p. 10).
Though the average magnetic field associated
with the 60 hertz current in
U.S. homes is 2 mG or lower, it can reach
12 mG in a small share of homes,
such as those with unusual electric wiring.
Values range as high as 1,000
mG in some occupational settings. People
may also be exposed briefly to 12
mG or higher magnetic fields from electric
razors and hair dryers, the
sides of computer monitors, or appliances
with large motors, such as
refrigerators.
Liburdy and Joan D. Harland, also at the national
lab, have now incubated
one type of breast cancer cell treated with
tamoxifen -- at concentrations
typical of those found in the breast cells
of women taking the drug -- in
the presence of the same two field strengths.
Untreated cells appeared to grow equally well
in each field. The growth
rate of cells treated with tamoxifen fell
by 40 percent in the 2 mG
environment but exhibited no drop-off in
the 12 mG field. Liburdy told
Science News, "We've shown that you can overcome
this field's suppression
of tamoxifen, but to do it you've got to
increase the drug dose by up to
10-fold."
Liburdy and Harland report their findings
in Bioelectromagnetics (vol. 18,
no. 8).
At last week's meeting, Liburdy also described
follow-up research on a
second type of breast cancer cell. Again,
both melatonin and tamoxifen
inhibited cell growth in a 2 mG environment
but failed to do so under the
influence of a 12 mG field.
At a Bioelectromagnetics Society meeting earlier
this year, Liburdy
presented laboratory data indicating that
12 mG magnetic fields from a
computer monitor, which have a slightly different
waveform than those
associated with home wiring or many appliances,
also erase the
antiproliferative action of a hormone --
in this case, melatonin.
"As basic science, this is very interesting
stuff," notes Richard Stevens
of the Pacific Northwest National Laboratory
in Richland, Wash. Most of the
new experiments were done with the most widely
studied line of breast
cancer cells, he notes. Moreover, "the [magnetic]
field levels used are
certainly relevant to humans."
While it's far too early to suggest that residential
fields pose a risk to
the efficacy of tamoxifen, Stevens does argue
that "this study provides the
rationale for wondering about and investigating
such implications."
Carl F. Blackman, a biophysicist with the
Environmental Protection Agency
in Research Triangle Park, N.C., has recently
confirmed Liburdy's finding
that magnetic fields can suppress melatonin's
action and is now probing the
ability of low-level fields to affect the
action of tamoxifen. In other
experiments, he finds that electromagnetic
fields can affect the
development of nerve cells when concentrations
of nerve growth factor are
too low.
What all these studies suggest, he says, is
that "in a system that is
stable and unstressed, you may see no effect
of these fields. But if you
stimulate it or depress it a little bit"
-- with drug treatment or
insufficient growth factors, for example
-- "the field may show an effect."
References:
Blackman, C.F., et al. 1996. Independent replication
of the 12-mG magnetic
field effect on melatonin and mcf-7 cells
in vitro. Eighteenth annual
meeting of the Bioelectromagnetics Society.
Victoria, British Columbia.
Harland, J.D. and R.P. Liburdy. 1997. Environmental
magnetic fields inhibit
the antiproliferative action of tamoxifen
and melatonin in a human breast
cancer cell line. Bioelectromagnetics 18.
Liburdy, R.P., et al. 1997. A 12mG (1.2 uTesla)
magnetic field inhibits
tamoxifen's oncostatic action in a second
human breast cancer cell line:
T47D. Second World Congress for Electricity
and Magnetism in Biology and
Medicine. Bologna, Italy.
Further Reading:
1995. EMFs on the brain? Science News 147(Jan. 21):44.
Adler, T. 1994. Study reaffirms tamoxifen's
dark side. Science News
145(June 4):356.
Edwards, D. 1988. Cells haywire in electromagnetic
field? Science News
133(April 2):216.
Ezzell, C. 1991. Power-line static. Science News 140(Sept. 28):202.
Fackelmann, K. 1994. Do EMFs pose breast cancer
risk? Science News 145(June
18):388.
Raloff, J. 1995. Drug of darkness. Science News 147(May 13):300.
______. 1994. Tamoxifen puts cancer on starvation
diet. Science News
146(Nov. 5):292.
______. 1994. Tamoxifen turmoil. Science News 146(Oct. 22):268.
______. 1994. Another way EMFs might harm
tissues. Science News 145(Feb.
19):127.
______. 1993. EMFs run aground. Science News 144(Aug. 21):124.
______. 1993. . . . but quenched by ubiquitous
hormone. Science News
144(Aug. 14):109.
______. 1992. Tamoxifen quandary. Science News 141(April 25):266.
______. 1990. EPA suspects ELF fields can
cause cancer. Science News
137(June 30):404.
Schmidt, K. 1991. Fickle fields: EMFs and
epidemiology. Science News
140(Nov. 30):357.
Sources:
Carl F. Blackman
U.S. Environmental Protection Agency
Mailstop Code 68
Research Triangle Park, NC 27711-2055
Robert P. Liburdy
Life Sciences Division
Lawrence Berkeley National Laboratory
MS-Building 934
One Cyclotron Road
Berkeley, CA 94720
Richard Stevens
Health Division, K4-28
Battelle Pacific Northwest Laboratory
Richland, WA 99352